Newfoundland and Labrador has a world class geology.
Earth scientists from all over the globe visit the province to study the record
of the earth's evolution preserved in its rocks. Not only does it have some of the
oldest rocks in the world, but it also has some unusual sequences of rocks which
tell a fascinating tale of colliding continents and disappearing oceans in the
geological past. Gros Morne National Park, in western Newfoundland, was declared an
UNESCO World Heritage site
in 1987 to recognise and preserve its unique geological landscape
which has been described as the 8th Wonder of the World.

The mineral resources of Newfoundland and Labrador are a direct product of its
geological history. The recent discovery of a major ore deposit at Voisey's Bay,
Labrador and the successful development of the Hibernia offshore oilfield highlight
a long tradition of mining and resource use dating back to prehistoric time when the
Maritime Archaic Indians quarried Ramah chert in northern Labrador and traded it
throughout the Atlantic provinces and states.

Earth's Changing Surface

The Earth's solid surface is a restless jigsaw of abutting, diverging, and
colliding slabs called tectonic plates. How plates behave forms the subject
known as plate tectonics. It is an important key to understanding why
continents collided in ancient Newfoundland and Labrador.

A slice through the Earth reveals a layered structure: a central metallic core
surrounded by a thick mantle and a thin outer crust.

The Layered Planet.
Cut open like a cake, today's Earth would show this layered structure.
Scientists deduce its inner layers from how these interfere with waves set
off by earthquakes.From Stephen Colman-Sadd and Susan A. Scott,
Newfoundland and Labrador: Travellers Guide to the Geology
(St. John's: Government of Newfoundland and Labrador, 1994).

The mantle is solid, but over very long periods of time most of it
behaves like plasticine and flows. The temperature difference between
the top and bottom of the mantle causes a circular flow called convection.
The uppermost mantle and crust form an outer shell of rigid plates.
The plates, and the continents they contain, move across the Earth's surface
on the convection currents.

Earth's Mantle in Motion.
Surrounding the Earth's core is the mantle, a 3,000 km thick layer of
dense magnesium- and iron-rich rock called peridotite. Heat generated by
radioactive decay and gravitational friction keeps part of the mantle
soft. Convection currents stir this semi-fluid layer. Molten rock
(magma) rises towards the surface of the Earth, cools, and sinks to be
reheated far below. On a smaller scale, convection currents can be seen
in a cup of hot coffee as milk warms and wells upwards in billows, then
cools and sinks again.From Stephen Colman-Sadd and Susan A. Scott,
Newfoundland and Labrador: Travellers Guide to the Geology
(St. John's: Government of Newfoundland and Labrador, 1994).

Plates grow by the addition of new rock from the mantle at mid-ocean ridges,
where the convection currents rise. The volcanic island of Iceland sits on top
of the Atlantic mid-ocean ridge. Plates are destroyed when they are carried down
into the mantle at subduction zones, such as the one off the coast of British Columbia.
In some places, the plates simply slide past each other along huge faults, like the San
Andreas Fault in California. Modern plate movements have parallels in the distant past
when the same processes built the Island of Newfoundland.

At mid-ocean ridges, rising convection currents melt mantle rock to form magma,
which then collects in magma chambers beneath the ridges.

When Plates Move Apart.
Currents in the soft mantle are powerful enough to crack Earth's crust
into enormous plates. As the plates separate, molten rock wells into the
expanding rift, then cools and hardens into new oceanic crust. At present
there are about twenty plates of different sizes and shapes moving about
the surface of the planet. Some underlie ocean, while others underlie
ocean and continent. Driven by convection currents in the mantle, plates
can move at the dizzying speed of ten centimetres a year.From Stephen Colman-Sadd and Susan A. Scott,
Newfoundland and Labrador: Travellers Guide to the Geology
(St. John's: Government of Newfoundland and Labrador, 1994).

Movement in the mantle cracks the overlying crust, allowing the magma
to escape and build volcanoes on the sea floor. Each time the crust cracks,
the rocks on either side of the ridge are moved a small distance sideways to
make room for the new volcanic rock. Repeated cracking gradually moves old
volcanoes away from the hot, active ridge area, and they become buried under
layers of sediment.

When a plate descends into the mantle at a subduction zone, part of it melts
in the hot interior of the Earth. The melted rock erupts on the surface as a
line of volcanoes.

When Plates Collide.
When plate edges override one another, one of the plates is forced down
into the hot mantle and melts. This process is called subduction. Molten
crust material is lighter than mantle, and it rises - melting its way
through the overlying solid rock and erupting as volcanic lava. When a
continental plate collides with an oceanic plate, the dense oceanic plate
is usually forced underneath the lighter continental plate. Continents
therefore endure by floating on the surface of the mantle, but ocean crust
is consumed by subduction. Because ocean floor is continuously created at
mid-ocean spreading centres, it is far younger than most continental rock.
The oldest continental rocks in Newfoundland and Labrador are 3,800
million years old, but the oldest rocks in the ocean are only 150 million
years old.From Stephen Colman-Sadd and Susan A. Scott,
Newfoundland and Labrador: Travellers Guide to the Geology
(St. John's: Government of Newfoundland and Labrador, 1994).

If subduction is at the edge of a continent, the volcanoes form mountains;
Mount St. Helens in the northwest United States is an example.
If the subduction is far from a continent, the result is a chain of volcanic islands,
known as an island-arc. Many of the islands in the Caribbean and the western Pacific
Ocean were formed in this way.

Ocean crust and mantle are easily subducted because they are made of heavy
basalt, gabbro and ultramafic rock, which "sink" into the mantle. Continent
crust, however, is made of lighter rocks like granite and it "floats" on the
mantle, instead of being subducted. When continents collide, rocks are crumpled
into great folds and large slabs of crust are pushed on top of each other to form
mountains. The Himalayas were built during the past 60 million years by the collision
of India and the rest of Asia. The Appalachian Mountain system, which extends into
Newfoundland, was formed in a similar way 400 million years ago, but it has since been
worn down by erosion.